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Biological research in developing countries: some ‘hotspots’

Biological research in developing countries: some ‘hotspots’. Harinder P.S. Makkar. Survey conducted. 48 active researchers (senior scientists and professors) contacted.... Asked: To give an example of a blunder which they noticed being conducted by a researcher in their laboratories

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Biological research in developing countries: some ‘hotspots’

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  1. Biological research in developing countries: some ‘hotspots’ Harinder P.S. Makkar

  2. Survey conducted • 48 active researchers (senior scientists and professors) contacted.... • Asked: • To give an example of a blunder which they noticed being conducted by a researcher in their laboratories • How research quality in developing countries can be enhanced ?

  3. Response to the survey • 45 out of 49 people responded • 90% mentioned: timely, important and a useful action; • praised the FAO/IAEA for taking initiative to correct the situation

  4. Summary of Results

  5. Improper statistical designs • Simplistic comparisons with no/improper control and no replications are common • Often students devise plans with huge number of samples that cannot be analysed statistically, because of improper design • Biology students have a phobia for mathematics (quantitative skills)

  6. Poor knowledge on the principles of equipment use For example: • Spectrophotometers: • single and dual wavelength, • Calibration, • use of glass and quartz cuvettes • Lambert-Beers law • Calibration of balances, pipettes, bomb calorimeter and of other equipment • Use of ‘New Techniques’ which are ‘fashionable’ without knowing the principles and their relevance

  7. Poor knowledge on the principles of equipment use • Separation using electrophoresis, Sephadex, and ion exchange resins • Preparation and storage of distilled water • Proper washing and storage of glassware

  8. Poor knowledge on the principles of bioprocesses For example: • How to measure enzyme activity? Linearity for time and concentration is rarely checked. • How to define and express enzyme activity? • Difference between enzyme activity and specific activity of enzymes. • How buffer solutions work? • Which buffers to use for which pH ranges? • How to prepare buffers of different molar concentration? • What is the difference between molar concentration (M), normality (N) and moles? • How to prepare standard acid/base solutions? • How to prepare and use standard curve? How to make dilutions? • Difference between rpm and g in centrifugation. • Lack of basic rumen fermentation and tissue biochemistry.

  9. Poor knowledge on the use of standardsand other quality control principles For example: • Standards rarely used for measurement of protein,fibre and other chemical constituents. • Recovery of a known amount of an analyte of interest rarely measured in the base material – effect of matrix is rarely investigated while using an assay system • Proper blanks and controls not used • Method validation of new or adapted methods rarely done.

  10. Poor knowledge on quality assurance procedures • There is no place in good scientific research for the view that ‘analysis is not worth spending time or money on’ • ‘Rubbish in, rubbish out’

  11. Improper general laboratory practices • Poor record keeping. • Generally loose sheets of papers used • Ideas, plans, discussions, instructions, problems encountered rarely recorded • Proper protocols for collection of ‘representative’ samples from a bulk material, fluid or tissue not followed • Proper drying and storage conditions not used • Literature accompanying equipment/chemicals rarely referred to before use (or kept near the equipment) • Experimental glassware/items not properly labeled • Lack of critical thinking while recording data – a robotic approach used

  12. Lack of information on laboratory safety issues For example: • A student thought he could bring his pregnant wife into the lab to help process samples from animals known to be contaminated with Listeria monocytogenes • A student seen removing gloves using his teeth after handling sodium cyanide – luckily student survived

  13. Improper presentation of results • While reporting a measured value, uncertainty (a measure of error associated with the value) is rarely given • Use of improper decimal points • Discussion of results poor

  14. Some suggestions (1) • Research should be conducted under constant supervision • Refresher courses should be conducted for supervisors & researchers • A course on ‘Research techniques’ should be compulsory for master students • Change the mindset of the students/researchers not to duplicate research conducted in developed countries. Highlight importance of relevant research • Motivate students to be a researchers (analytical minded) even though the aim of the student is not to go for research-oriented jobs

  15. Some suggestions (2) • Supervisors should take great pain in explaining all details of the changed/new methodologies. It is important to NOT assume anything; even though things may appear to be totally obvious • There should be a good communication with respect to providing full details of the experimental protocols and objectives of the project between the researcher and the Centralized Laboratory analysing samples • Extensive literature search before starting to design an experiment. The researcher should have clear ideas on limitations of methods, techniques and tools before conducting experiment • Before starting to design an experiment, important to make the hypothesis or question very clear. Avoid confounding by answering one question after the other. Analyse and interpret results according to the initial hypothesis

  16. Some suggestions (3) • The researcher should have an understanding of the technical background of the equipment • Before starting on in vitro or in vivo experiment, make sure that enough consumable material is available • Students should not be spoon fed nor left in isolation. They should develop protocols and organise research which should be discussed in a group. Result discussion and data presentation skills should be improved. • Proper selection of professors who teach and guide students at the post graduate level (‘mediocrity breeds mediocrity’). • Researcher should ensure use of proper statistical design and validated methods. Free communication with supervisor and group members should be encouraged

  17. Recap • Improper statistical designs • Poor knowledge on the principles of equipment use • Poor knowledge on the principles of bioprocesses • Poor knowledge on the use of standards and other quality control principles • Improper general laboratory practices • Lack of information on laboratory safety issues • Improper presentation of results • Poor presentation skills

  18. The challenge • In addition to enhancing theoretical and practical knowledge on biological systems and research methodology, build confidence enabling better use of common sense

  19. Thank you (Press ESC to finish or close the browser)

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